2022-07-20 10:32:18 +00:00
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use crate::dsp::{DspNode, LedPhaseVals, NodeContext, NodeId, ProcBuf, SAtom};
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2022-07-19 09:44:54 +00:00
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use crate::nodes::{NodeAudioContext, NodeExecContext};
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/// A simple amplifier
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#[derive(Debug, Clone)]
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pub struct Formant {
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inv_sample_rate: f32,
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phase: f32,
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}
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impl Formant {
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pub fn new(_nid: &NodeId) -> Self {
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Self { inv_sample_rate: 1.0 / 44100.0, phase: 0.0 }
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}
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pub const freq: &'static str = "Formant freq\nBase frequency to oscilate at\n";
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pub const form: &'static str = "Formant form\nFrequency of the formant\n";
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2022-07-19 09:44:54 +00:00
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pub const atk: &'static str =
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"Formant atk\nFormant attack bandwidth, controls the general bandwidth";
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pub const dcy: &'static str =
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"Formant dcy\nFormant decay bandwidth, controls the peak bandwidth";
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pub const sig: &'static str = "Formant sig\nGenerated formant signal";
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2022-07-19 09:44:54 +00:00
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pub const DESC: &'static str = r#"A direct formant synthesizer
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This generates a single formant from a given frequency, formant frequency, as well as attack and decay frequencies.
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The attack and decay frequencies both control the bandwidth of the formant, decay the peak of the bandwidth, attack peak.
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"#;
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pub const HELP: &'static str = r#"Formant - Single formant synthesizer
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This is a formant synthesizer that directly generates the audio, no filters needed.
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"#;
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}
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impl DspNode for Formant {
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fn outputs() -> usize {
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1
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}
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fn set_sample_rate(&mut self, srate: f32) {
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self.inv_sample_rate = 1.0 / srate;
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}
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fn reset(&mut self) {
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self.phase = 0.0;
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}
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#[inline]
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fn process<T: NodeAudioContext>(
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&mut self,
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ctx: &mut T,
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_ectx: &mut NodeExecContext,
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_nctx: &NodeContext,
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_atoms: &[SAtom],
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inputs: &[ProcBuf],
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outputs: &mut [ProcBuf],
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_ctx_vals: LedPhaseVals,
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) {
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2022-07-20 10:32:18 +00:00
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use crate::dsp::{denorm, inp, out};
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let base_freq = inp::Formant::freq(inputs);
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let formant_freq = inp::Formant::form(inputs);
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2022-07-19 09:44:54 +00:00
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let attack_freq = inp::Formant::atk(inputs);
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let decay_freq = inp::Formant::dcy(inputs);
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let out = out::Formant::sig(outputs);
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for frame in 0..ctx.nframes() {
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// get the inputs
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let base_freq = denorm::Sampl::freq(base_freq, frame);
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let formant_freq = denorm::Sampl::freq(formant_freq, frame);
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let attack_freq = denorm::Sampl::freq(attack_freq, frame);
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let decay_freq = denorm::Sampl::freq(decay_freq, frame);
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// where the two decays meet
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let carrier_center = decay_freq / (attack_freq + decay_freq);
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// where they meet in amplitude
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let carrier_lowest_amplitude =
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(-std::f32::consts::TAU * base_freq * carrier_center * decay_freq).exp();
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// turn it into a triangle wave
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let carrier_attack = (1.0 - self.phase) / carrier_center;
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let carrier_decay = self.phase / (1.0 - carrier_center);
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// actual triangle wave
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let carrier_base = 1.0 - carrier_attack.min(carrier_decay);
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// smoothstep
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let carrier =
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carrier_base * carrier_base * (3.0 - 2.0 * carrier_base) * carrier_lowest_amplitude
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+ (1.0 - carrier_lowest_amplitude);
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// multiple of the frequency the modulators are at
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let multiple = formant_freq / base_freq;
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// round them to the closest integer of the formant freq
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let freq_a = multiple.floor();
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let freq_b = freq_a + 1.0;
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// and how much to lerp between them
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let blend = multiple.fract();
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// get the true modulator
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let modulator = (1.0 - blend) * (std::f32::consts::TAU * self.phase * freq_a).cos()
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+ blend * (std::f32::consts::TAU * self.phase * freq_b).cos();
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// entire wave
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let wave = carrier * modulator;
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out.write(frame, wave);
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}
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}
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}
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